Configurable simulator with testing capabilities

ABSTRACT

The present disclosure relates to a configurable simulator with testing capabilities, comprising a simulation controller and a plurality of configurable modular cards. The simulation controller determines configuration parameters of the cards and exchanges configuration messages with the cards. The simulation controller also receives and processes test notifications from the cards. Each card comprises a configurable input/output unit comprising a plurality of configurable inputs and outputs, and a power supply comprising a plurality of configurable power supply circuits. The input/output unit exchanges configuration messages with the simulation controller and sends the test notification. Each card further comprises a processor for configuring the configurable input/output unit, and the power supply. The processor also executes a simulation code to implement a functionality of the simulator. The processor further tests the input/output unit and the power supply, monitors the execution of the simulation code, and generates the test notification based on test results.

TECHNICAL FIELD

The present disclosure relates to the field of simulators. More specifically, the present disclosure relates to a configurable simulator with testing capabilities.

BACKGROUND

Flight simulators are used by commercial airlines and air forces to train their pilots to face various types of situations. As every aircraft has its particularities, flight simulators are usually built to train pilots on one type or similar types of aircrafts.

A flight simulator is divided in groups of components, each group corresponding to a specific functionality of the aircraft. For example, a first group of components are used to simulate the information displayed on the displays, a second group of components are used to simulate the motion of the aircraft, a third group of components are used to simulate the electric circuits, another group of components are used to simulate the hydraulic circuits, etc. The groups of components are centrally controlled by one or several processors.

Therefore, there is a need for a configurable simulator with testing capabilities.

SUMMARY

According to a first aspect, the present disclosure provides a configurable simulator with testing capabilities. The simulator comprises at least one simulation controller and a plurality of configurable modular cards. The simulation controller comprises an input/output unit for receiving a broadcast message from a plurality of configurable modular cards, and for sending a broadcast response message with configuration parameters to the plurality of configurable modular cards. The input/output unit further receives a test notification with test results from one of the plurality of configurable modular cards. The simulation controller also comprises a processor for determining the configuration parameters of the plurality of configurable modular cards based on a pre-defined configuration of the simulator, and for processing the test results to determine an operational status of the one of the plurality of configurable modular cards. Each card comprises a configurable input/output unit comprising a plurality of configurable inputs and outputs and a power supply comprising a plurality of configurable power supply circuits. The configurable input/output unit has a predefined output for sending the broadcast message and a predefined input for receiving the broadcast response message. Each card further comprises at least one processor for executing an input/output configuration code, to configure the plurality of inputs and outputs of the configurable input/output unit, based on the broadcast response message received by the configurable input/output unit. The processor also executes a power supply configuration code, to configure the plurality of power circuits of the power supply, based on the broadcast response message received by the configurable input/output unit. The processor further executes a simulation code to implement a functionality of the simulator. The executed simulation code is determined based on the broadcast response message received by the configurable input/output unit. The processor executes testing code for generating testing signals to the plurality of inputs and outputs of the configurable input/output unit configured based on the broadcast response message. The execution of the testing code also generates testing signals to the plurality of power circuits of the power supply configured based on the broadcast response message. The execution of the testing code further monitors the execution of the simulation code. The processor also generates the test notification sent by the configurable input/output unit to the simulation controller with the test results of the testing code executed by the processor.

In a particular aspect, configuring the plurality of inputs and outputs of the configurable input/output unit comprises performing a network configuration of the inputs and outputs.

In another particular aspect, configuring the plurality of power circuits of the power supply comprises determining at least one of: a specific amperage and a specific voltage of the power delivered by the specific power circuit.

In still another particular aspect, configuring the plurality of inputs and outputs of the configurable input/output unit comprises determining which inputs and outputs are used to receive and send data related to a specific sub-functionality.

In yet another particular aspect, the execution of the testing code is triggered by the reception of a test request received from the simulation controller.

BRIEF DESCRIPTION OF THE DRAWINGS

Embodiments of the disclosure will be described by way of example only with reference to the accompanying drawings, in which:

FIG. 1 is a block diagram of a configurable modular card;

FIG. 2 is a block diagram of a configurable simulator including several of the configurable modular cards of FIG. 1, according to a first aspect;

FIG. 3 is a block diagram of a configurable simulator including several of the configurable modular cards of FIG. 1, according to another aspect;

FIG. 4 is a bloc diagram of the configurable modular card of FIG. 1, according to still another aspect;

FIG. 5 illustrates a method for operating a configurable simulator including a plurality of the configurable modular cards of FIG. 1, according to yet another aspect; and

FIG. 6 illustrates an exemplary flight simulator including several of the configurable modular cards of FIG. 1;

FIG. 7 illustrates an example of a semi-automatic pre-acceptance test;

FIG. 8 illustrates a simulator comprising a testing platform to perform pre-acceptance testing of software components/configurable modular cards;

FIG. 9 illustrates the simulator of claim 8 according to another aspect;

FIG. 10 illustrates a method for performing pre-acceptance testing;

FIG. 11 illustrates a graphical representation of a hardware component and corresponding pre-acceptance testing scenarios;

FIG. 12 illustrates a graphical representation of a pre-acceptance testing scenario for software component;

FIG. 13 illustrates a graphical representation of a pre-acceptance testing scenario for a component comprising hardware and software aspects;

FIG. 14 illustrates a report generated on a per component or a per configurable modular card basis; and

FIG. 15 illustrates a schematic representation of an exemplary sub-division of tests including pre-acceptance tests.

DETAILED DESCRIPTION

The foregoing and other features will become more apparent upon reading of the following non-restrictive description of illustrative embodiments thereof, given by way of example only with reference to the accompanying drawings. Like numerals represent like features on the various drawings.

Various aspects of the present disclosure generally address one or more of the problems of simulators having a plurality of computing components for executing a simulation.

The simulators mentioned in the present disclosure may be used for different simulation purposes. For example, a first type of simulator may consist of a vehicular simulator, such as an aircraft simulator, a terrestrial vehicle simulator, a boat simulator, an underground simulator, a mining simulator or a nuclear plant simulator.

A simulator is a complex system generally comprising a plurality of components. A first type of component consists of a computing component, comprising a processor for executing a specific simulation software (simulation software and simulation code are used interchangeably in the present disclosure). A computing component generally receives data, processes the received data by means of the specific simulation software to generate new data, and transmits the new data. A computing component may also be capable of interacting with one or several dedicated hardware components, such as sensors, mechanical actuators, pneumatic actuators, hydraulic actuators, displays, switches, lights, electric components, etc. The computing component may receive data from a dedicated hardware component and/or send commands to the dedicated hardware component (e.g. receive data from a sensor and send actuating commands to an actuator). The computing components also exchange data with each other, to execute and synchronize the simulation.

The simulator is generally implemented as a plurality of sub-systems for implementing a plurality of functionalities of the simulator. Each sub-system comprises a plurality of computing components and a plurality of dedicated hardware components. The computing components are centrally controlled by one or several dedicated entities having a processor executing control software. The computing components are usually implemented by dedicated cards; each dedicated card having specific electronic components designed to implement a specific functionality or sub-functionality of the simulator. Additionally, each dedicated card may only be capable of executing dedicated software stored in a memory of the dedicated card. Thus, when such a dedicated card is not operating properly, the only alternative is to repair the dedicated card (possibly interrupting the simulation) or to replace the dedicated card with the exact same type of dedicated card (which may not be available immediately or may be very expensive).

The present disclosure introduces a configurable modular card, which can be configured to play the role of several of the aforementioned computing components. Thus, the simulator is no longer dependent on multiple dedicated cards, which are replaced by instances of the configurable modular card. The configurable modular card comprises several configurable electronic components (such as a configurable input/output unit, a configurable power supply). The simulation software executed by a particular configurable modular card is also configurable. The configurable modular cards are configured and controlled by one or several dedicated entities having a processor executing a configuration and control software. Thus, when a specific configurable modular card implementing a critical functionality of the simulator is not operating properly, another configurable modular configurable card of the simulator can be reconfigured to implement the critical functionality in place of the defective card.

FIG. 6 illustrates an exemplary flight simulator 600 including a simulation controller 610 and several configurable modular cards (631, 632, 641, 642, 652, 661 and 671). The configurable modular cards hierarchically implement two exemplary sub-systems (engines 620 and landing gear 650) of the flight simulator 600. FIG. 6 will be described with more details later in the description.

Configurable Modular Card

Referring now to FIG. 1, a configurable modular card 100 for use in a simulator is represented.

The card 100 comprises a board 10 and a processor 20 mounted on the board. Although a single processor 20 is represented in FIG. 1, the card 100 may comprise several processors operating in parallel, as is well known in the art. Additionally, each processor may be a single core or a multicore processor. The at least one processor may execute a simulation code, or a portion of the simulation code, to implement a functionality of the simulator. Examples of functionalities of the simulator include without limitation: simulating information displayed on a display, simulating a motion of an aircraft, simulating electric circuits of an aircraft, simulating hydraulic circuits of an aircraft, simulating a heartbeat, simulating a bodily function, and/or any other type of simulation code known.

The card 100 also comprises a memory 30 mounted on the board 10 and in electronic communication with the processor 20. Although a single memory 30 is represented in FIG. 1, the card 100 may comprise several memories or banks of memories. Each memory present on the card 100 may be dedicated to a single processor of the card 100, or may be shared between several processors of the card 100.

The card 100 further comprises a configurable input/output (I/O) unit 40. The simulation code executed by the processor 20 may be received through the configurable I/O unit 40. The configurable I/O unit 40 comprises a plurality of configurable inputs and outputs. For illustration purposes, the configurable I/O unit 40 represented in FIG. 1 comprises a configurable input 41, a configurable output 42 and a configurable input/output 43. The configurable input 41 is capable of receiving data from one or several other components not represented in FIG. 1. The configurable output 42 is capable of transmitting data to one or several components not represented in FIG. 1. The configurable input/output 43 is capable of exchanging (transmitting and receiving) data with one or several components 110.

The configurable I/O unit 40 may also comprise one or several switches. For example, an optional switch 44 is represented in FIG. 1. The switch 44 is capable of at least one of the following: switching, multiplexing and de-multiplexing signals exchanged between the configurable input/output 43 and other simulation components 110.

The configurable I/O unit 40 may comprise any number of configurable inputs and outputs, as long as it is compatible with the size and shape of the board 10, and with the space left by the other electronic components on the board 10. Each configurable input and output of the configurable I/O unit 40 is capable of communicating with a single or with a plurality of other simulation components, such as for example: panel, electronics, sensors, motors and actuators and/or guidance of any type of aircraft or vehicle, aircraft avionics, etc.

When the processor 20 executes a simulation code to implement a functionality of the simulator, the processor 20 may process data received by the configurable I/O unit 40 from other components, and generate data sent by the configurable I/O unit 40 to other components.

The configurable inputs and outputs of the configurable I/O unit 40 provide communication capabilities to the card 100 in accordance with one or several types of communication protocols. For instance, the configurable I/O unit 40 may include at least one Ethernet board for receiving/transmitting data via the Ethernet protocol. Alternatively or concurrently, the configurable I/O unit 40 may include a Wireless Fidelity (Wi-Fi) board for receiving/transmitting data via the Wi-Fi protocol. The configurable I/O unit 40 may also include a High-Definition Multimedia Interface (HDMI) board, for transmitting video (and audio) data to a screen. Other types of inputs and outputs may be implemented by the configurable I/O unit 40, based on the various types of other simulation components (e.g. 110) with which the configurable modular card 100 is exchanging data.

The configurable I/O unit 40 further sends a broadcast message and receives a broadcast response message. The broadcast message may be sent by different outputs of the configurable I/O unit 40 and the broadcast response message may be received by different inputs of the configurable I/O unit 40. Also, different communication protocols may be used for sending the broadcast message and receiving the broadcast response message. In a particular aspect, the configurable I/O unit 40 has a predefined output for sending the broadcast massage and a predefined input for receiving the broadcast response message. In the embodiment illustrated in FIG. 1, the broadcast message 120 is sent and the broadcast response message 121 is received via input/output 43. Alternatively, the broadcast message 120 may be sent via output 42 and the broadcast response message 121 received via input 41. In another embodiment, the broadcast message 120 may be sent via an Ethernet board of the configurable I/O unit 40, and the broadcast response message 121 may be received via a Wi-Fi board of the configurable I/O unit 40. Alternatively, the broadcast message 120 may be sent via a Wi-Fi board of the configurable I/O unit 40, and the broadcast response message 121 may be received via an Ethernet board of the configurable I/O unit 40.

The predefined output and the predefined input may be permanently stored in the memory 30, when the card 100 is manufactured/pre-configured before usage. Upon startup of the card 100, the processor 20 may execute a bootstrap program permanently stored in the memory 30. The bootstrap program includes the sending of the broadcast massage 120 over the memorized predefined output and the receiving of the broadcast response message 121 over the memorized predefined input.

In a particular embodiment, the broadcast message 120 comprises a configuration request, an identification of the card 100 (e.g. a serial number), and an identification of the predefined input (e.g. an Ethernet or an Internet Protocol (IP) address). The broadcast message 120 is received by a configuration component. The configuration component determines configuration parameters based on the identification of the card 100. Then, the configuration component transmits the configuration parameters to the card 100, via the broadcast response message 121 sent to the predefined input. The configuration component may determine the configuration parameters based on many possible variants (e.g. replacement card needed, processing capability required, simulation to be performed, physical I/O capacity, etc.). The configuration parameters may include a list of the other configurable modular cards with which the card 100 must communicate to perform the simulation. For example, the configuration parameters may include a list of cards and their corresponding sub-functionalities, so that the card 100 may communicate directly with the other cards upon execution of the simulation, by identifying that a sub-functionality is performed by a specific card from the list. The configuration parameters may also include a list of dedicated hardware components with which the card 100 must communicate to perform the simulation. One of the other simulation components 110 represented in FIG. 1 may implement the configuration component.

A broadcast message 120 is used since the card 100 does not necessarily knows the configuration component. By sending the message 120 in a broadcast mode, the card 100 ensures that the message 120 is received by the configuration component (as well as by other entities). The configuration component receives the broadcast message 120, determines that it is the intended recipient, processes the broadcast message 120, and sends back the broadcast response message 121.

The card 100 also comprises a bus 50, electronically connected with the configurable I/O unit 40, with the at least one processor 20 of the board 10, and with the at least one memory 30 of the board 10. The bus 50 provides electronic data exchange there between. For example, the processor 20 reads data in the memory 30 via the bus 50, processes the data, and transmits the processed data via the bus 50 to the configurable I/O unit 40 (for further transmission by an output of the configurable I/O unit 40 to another simulation component). Similarly, the processor 20 receives data from the configurable I/O unit 40 (the data was received by an input of the configurable I/O unit 40 from another simulation component) via the bus 50, processes the data, and transmits the processed data via the bus 50 to the memory 30 for memorization therein.

Input/output (I/O) configuration code (not represented in FIG. 1) is stored in the memory 30. The I/O configuration code is executed by the processor 20 to configure the plurality of inputs and outputs (e.g. 41, 42 and 43) of the configurable I/O unit 40, based on the received broadcast response message 121.

The configuration of the configurable I/O unit 40 may include a network configuration of its inputs and outputs. Network configuration is well known in the art, and depends on the specific types of inputs and outputs, and on the specific types of communication protocols they support. For instance, the configuration of an Ethernet input/output may include the configuration of its IP address. The configuration of a Wi-Fi input/output may include the configuration of a Service Set Identifier (SSID) and a wireless key, as well as its IP address. In these examples, the IP address, SSID and wireless keys are network configuration parameters transmitted to the card 100 via the broadcast response message 121.

The configuration of the configurable I/O unit 40 may include a functional configuration of its inputs and outputs. For instance, a first sub-functionality of the card 100 is associated with a first input/output. All data exchanged with other simulation components (e.g. 110) when executing the first sub-functionality are transmitted and received with the first input/output. Another sub-functionality of the card 100 is associated with a second input/output. All data exchanged with other simulation components when executing the second sub-functionality are transmitted and received with the second input/output. For example, the configurable I/O unit 40 may have two video outputs. A first video output is connected to a video screen of a trainee and the second video output is connected to a video screen of an instructor. The processor 20 runs simulation software which generates specific video data for the trainee (first sub-functionality) and specific video data for the instructor (second sub-functionality). The received broadcast response message 121 provides the following configuration: specific video data for the trainee shall be transmitted via the first video output and specific video data for the instructor shall be transmitted via the second video output.

Alternatively, the functional configuration of the inputs and outputs of the configurable I/O unit 40 may consist in determining which inputs and outputs within the plurality of inputs and outputs are used to exchange data with another simulation component. Referring to the previous example where the configurable I/O unit 40 has two video outputs, the received broadcast response message 121 provides the following configuration: video data sent to a first screen (e.g. the trainee screen) shall be transmitted via the first video output and video data sent to a second screen (e.g. the instructor screen) shall be transmitted via the second video output. Examples of parameters of the broadcast message also include: sound data, sensor data, aircraft protocol data, vehicle protocol data, etc.

The card 100 also comprises a power supply 60. The power supply 60 receives an entry power 65 of a predetermined voltage, and comprises a plurality of configurable power supply circuits. For illustration purposes, the power supply 60 represented in FIG. 1 comprises two configurable power supply circuits 61 and 62. The power supply 60 may comprise any number of configurable power supply circuits, as long as it is compatible with the size and shape of the board 10, and with the space left by the other electronic components on the board 10.

A configurable power supply circuit provides power to one or several electronic components of the card 100. Additionally, some of the configurable power supply circuits may provide power to electronic components of one or several other simulation components (e.g. 110). For illustration purposes, the configurable power supply circuit 61 represented in FIG. 1 provides power 66 to the configurable I/O unit 40 and the configurable power supply circuit 62 provides power 67 to the processor 20. Although not represented in FIG. 1 for simplification purposes, the configurable power supply circuits 61 and 62 may also provide power to the bus 50, the memory 30, and to other simulation component(s) 110. Alternatively, additional configurable power supply circuit(s) may be used to provide power to the bus 50, the memory 30, and to other simulation component(s) 110. For example, the other simulation component(s) 110 may consist of one or several screens for displaying data, the screens receiving power from at least one of the configurable power supply circuit(s) of the power supply unit 60.

Power supply configuration code (not represented in FIG. 1) is stored in the memory 30. The power supply configuration code is executed by the processor 20, to configure the plurality of power circuits (e.g. 61 and 62) of the power supply 60, based on the received broadcast response message 121.

The configuration of each specific power circuit may consist of a specific amperage (the voltage is similar to the entry power 65), a specific voltage (the amperage is similar to the entry power 65), or a specific combination of amperage and voltage, for the power delivered by the specific power circuit. If a power circuit has several outputs for delivering power to several entities, each power output may be configured individually.

The broadcast response message 121 comprises power configuration parameters (e.g. amperage and/or voltage) for each configurable power circuit of the power supply 60. In the embodiment illustrated in FIG. 1, the same broadcast message 120 and broadcast response message 121 are used for configuring the configurable I/O unit 40 and the power supply 60. Alternatively, a dedicated broadcast message/broadcast response message may be used for respectively configuring the configurable I/O unit 40 and the power supply 60.

One or several power circuits of the power supply 60 may have a default configuration, to allow proper operations of the card 100 until the broadcast response message 121 comprising the power configuration parameters is received. The default configuration of some of the power circuits may be overridden by the received power configuration parameters, while the default configuration of some of the power circuits may be maintained.

The configuration codes (I/O configuration code and power supply configuration code) may be permanently stored in the memory 30, when the card 100 is manufactured/pre-configured before usage. Upon startup of the card 100, the processor 30 may execute the configuration codes, after reception of the broadcast response message 121. The configuration codes may also be executed at other moments: after a reset of the card 100, after a failure (software or hardware) of the card 100 requiring a complete reconfiguration, etc. The configuration parameters of the configurable I/O unit 40 and of the power supply 60, received via the broadcast response message 121, can be permanently stored in the memory 30, to be available to the configuration codes at any time.

Alternatively, the configuration codes may not be initially present in the memory 30, but downloaded from an external entity (e.g. one of the other simulation components 110) and stored in the memory 30 for further use. The predefined output and the predefined input (e.g. 43) of the configurable I/O unit 40 can be used for performing the download of the configuration codes. Broadcast message 120/broadcast response message 121 can be used for this purpose; or additional broadcast message/broadcast response message dedicated to the download of the configuration codes can be used.

Testing code (not represented in FIG. 1) is stored in the memory 30. The testing code is executed by the processor 20 to generate testing signals to the plurality of inputs and outputs of the configurable I/O unit 40 configured based on the broadcast response message 121. The testing code executed by the processor 20 also generates testing signals to the plurality of power circuits of the power supply 60 configured based on the broadcast response message 121.

The testing signals generated to the plurality of inputs and outputs of the configurable I/O unit 40 allow a verification that the inputs and outputs are operating in conformance with the configuration parameters received via the broadcast response message 121. The verification may include a verification of the network configuration of the inputs and outputs. For instance, the testing signals may permit a determination that a specific input or a specific output are respectively capable of receiving and transmitting data, at a specified throughput, with a specified delay, with a specified packet loss rate, etc. The verification may also include a verification of the network connectivity of the inputs and outputs with another simulation component.

Similarly, the testing signals generated to the plurality of power circuits of the power supply 60 allow a verification that the power circuits are operating in conformance with the configuration parameters received via the broadcast response message 121. For instance, the testing signals may permit a determination that a specific power circuit is operating at a specified voltage and/or amperage.

Similarly to the configuration codes, the testing code may be permanently stored in the memory 30, when the card 100 is manufactured/pre-configured before usage. Alternatively, the testing code may not be initially present in the memory 30, but downloaded from an external entity (e.g. one of the other simulation components 110) and stored in the memory 30 for further use.

If several processors are mounted on the board 10, the configurations codes and the testing code may be executed by the same processor or by different processors. Additionally, the testing code may be divided in multiple configurable modular cards executed by different processors operating in parallel.

Configurable Simulator with a Plurality of Configurable Modular Cards

Referring now concurrently to FIGS. 1 and 2, a simulator 200 with a plurality of configurable modular cards is represented.

The simulator 200 comprises a configuration component 210 and a plurality of configurable modular cards 101, 102, 103 and 104. The plurality of configurable modular cards 101, 102, 103 and 104 are instances of the configurable modular card 100, which has been previously described with reference to FIG. 1. Although four instances of the configurable modular card 100 have been represented in FIG. 2, the simulator 200 may comprise any number of these cards.

The configuration component 210 includes an input/output (I/O) unit 211 and a processor 212. The configuration component 210 may include additional electronic components, such as additional processors, at least one memory, a bus, a power unit; not represented in FIG. 2 for simplification purposes.

The configuration component 210 configures the plurality of configurable modular cards 101, 102, 103 and 104. The configuration of instances of the configurable modular card 100 has been previously described with reference to FIG. 1. Each configurable modular card (e.g. 101) sends a broadcast message (on a predefined output of its configurable I/O unit 40) to the configuration component 210. The broadcast message is received by the I/O unit 211 of the configuration component 210, and transmitted to the processor 212. The processor 212 determines configuration parameters for the configurable modular card (e.g. 101) and transmits the configuration parameters to the I/O unit 211. The I/O unit 211 sends a broadcast response message with the configuration parameters to the configurable modular card (e.g. 101). The broadcast response message is received on a predefined input of the configurable I/O unit 40 of the configurable modular card (e.g. 101).

The processor 20 of each configurable modular card (e.g. 101) executes its I/O configuration code to configure the plurality of inputs and outputs of its configurable input/output unit 40 based on the received broadcast response message.

The processor 20 of each configurable modular card (e.g. 101) executes its power supply configuration code to configure the plurality of power circuits of its power supply 60 based on the received broadcast response message.

The simulator 200 may comprise more than one configuration component 210. For instance, the configuration component 210 may be responsible for configuring the configurable modular cards 101 and 102, and another configuration component (not represented in FIG. 2) may be responsible for configuring the configurable modular cards 103 and 104. Furthermore, the configuration component may be implemented by a configurable modular card 100. For example, the configurable modular card 103 may be configured by the configuration component 210, and implement the functionality of a configuration component for the configurable modular card 104.

When a configurable modular card (e.g. 101) of the simulator 200 is configured, its processor 20 is capable of executing a simulation code to implement a functionality of the simulator 200. Its configurable I/O unit 40 is capable of exchanging (receiving and sending) data with at least one other simulation component. Executing the simulation code to implement the functionality of the simulator 200 comprises processing the data received by the configurable I/O unit 40 and generating the data sent by the configurable I/O unit 40. The specific inputs and outputs of the configurable I/O unit 40 used for exchanging a specific type of communication data or for communicating with a specific other simulation component are determined by the I/O configuration code executed by the processor 20.

The other simulation component may consist of another configurable modular card 100 or of a dedicated hardware component 220 (e.g. a display, a light, a mechanical actuator, etc.) different from the configurable modular card 100. For example, as illustrated in FIG. 2, the configurable modular card 101 exchanges data with the configurable modular card 102. The configurable modular card 102 exchanges data with the configurable modular cards 101 and 104. The configurable modular card 103 exchanges data with the configurable modular cards 104 and the dedicated hardware component 220. The configurable modular card 104 exchanges data with the configurable modular cards 102 and 103.

A dedicated hardware component (e.g. 220) such as a display, a light, a mechanical actuator, is under the control of one or several configurable modular cards (e.g. 103). In this case, the data exchanged there between consist of commands generated by the simulation software executed by the processor 20 of the configurable modular cards (e.g. 103). The commands are sent to the dedicated hardware component (e.g. 220) to trigger an event representative of the current state of the simulation. Such events may comprise: displaying data on a display, switching on or off a light, activating a mechanical actuator (e.g. to move a seat in which a trainee is sitting), controlling analog gauge (to actuate a gauge for equipment such as for example an altimeter, a pump gauge, a compressor gauge, etc.). Alternatively, a dedicated hardware component (e.g. 220) may consist of a sensor, and the data exchanged between the sensor and one or several configurable modular cards (e.g. 103) consist in data collected by the sensor and sent to the configurable modular card(s).

The power supply configuration code executed by the processor 20 of a configurable modular card (e.g. 103) configures the power supply circuits of its power unit 60 to deliver power to electronic components (e.g. processor 20, configurable I/O unit 40) of the configurable modular card (e.g. 103). More specifically, the configuration comprises determining at least one of specific amperage or a specific voltage of the power delivered to a specific electronic component. Additionally, some of the power supply circuits of the power unit 60 may be configured to deliver power to electronic components of another entity. For instance, some of the power supply circuits of the power unit 60 of the configurable modular card 103 may be configured to deliver power to electronic components of the configurable modular card 104 or to electronic components of the dedicated hardware component 220.

Configurable Simulator with Distributed Simulation Capabilities

Referring now concurrently to FIGS. 1 and 3, a simulator 300 comprising a plurality of configurable modular cards for performing a distributed simulation is represented.

The simulator 300 comprises a simulation controller 310 and a plurality of configurable modular cards 101, 102, 103 and 104. The plurality of configurable modular cards 101, 102, 103 and 104 are instances of the configurable modular card 100, which has been previously described with reference to FIG. 1. Although four instances of the configurable modular card 100 have been represented in FIG. 3, the simulator 300 may comprise any number of these cards.

The simulation controller 310 corresponds to the configuration component 210 represented in FIG. 2, but with additional capabilities for managing a distributed simulation and for reconfiguring the configurable modular cards when appropriate.

The simulation controller 310 includes an input/output (I/O) unit 311 and a processor 312. The simulation controller 310 may include additional electronic components, such as additional processors, at least one memory, a bus, a power unit; not represented in FIG. 3 for simplification purposes.

The simulation controller 310 configures the plurality of configurable modular cards 101, 102, 103 and 104. The configuration of instances of the configurable modular card 100 has been previously described with reference to FIG. 1. Each configurable modular card (e.g. 101) sends a broadcast message to the simulation controller 310. The broadcast message is received by the I/O unit 311 of the simulation controller 310, and transmitted to the processor 312. The processor 312 determines configuration parameters for the configurable modular card (e.g. 101) and transmits the configuration parameters to the I/O unit 311. The I/O unit 311 sends a broadcast response message with the configuration parameters to the configurable modular card (e.g. 101). The configurable I/O unit 40 receives the broadcast response message.

The configuration parameters are determined based on a pre-defined configuration of the simulator. For instance, as illustrated in FIG. 3, the simulator 300 may comprise two sub-systems 350 and 360. The first sub-system 350 implements a first functionality of the simulator, for example simulating a motion of an aircraft. The second sub-system 360 implements a second functionality of the simulator, for example simulating information displayed on a display. Functionalities may be divided in sub-functionalities and the pre-defined configuration of the simulator determines which configurable modular cards implement which functionalities or sub-functionalities. Examples of systems include: flight control, autopilot system, navigation system, power management system, etc.

The processor 20 of each configurable modular card (e.g. 101) generates the broadcast message sent by its configurable I/O unit 40 to the simulation controller 310.

The processor 20 of each configurable modular card (e.g. 101) executes its I/O configuration code to configure the plurality of inputs and outputs of its configurable input/output unit 40, based on the broadcast response message (comprising the configuration parameters) received by its configurable I/O unit 40.

The processor 20 of each configurable modular card (e.g. 101) executes its power supply configuration code to configure the plurality of power circuits of its power supply 60, based on the broadcast response message (comprising the configuration parameters) received by its configurable I/O unit 40.

The processor 20 of each configurable modular card (e.g. 101) executes a simulation code to implement a functionality of the simulator, the executed simulation code being determined based on the broadcast response message (comprising the configuration parameters) received by its configurable I/O unit 40. The simulation code may decouple the hardware from the software by including tags referring to each hardware component and hardware sub-component which is involved in the simulation. For example, the input/output of the I/O unit 40 to be used is tagged and reference is made to the tag in the simulation code rather than to the input/output themselves. By tagging the hardware components and hardware sub-components involved in the simulation, and referring to the tags in the simulation code, it becomes possible to modify the modular card 100 and the interactions between the modular cards and the other components, by simply re-assigning the tags to other hardware components and hardware sub-components, as needed, and even on the fly or dynamically.

When a specific functionality of the simulator is divided in several sub-functionalities, the processors 20 of several configurable modular cards (e.g. 101 and 102, or alternatively 103 and 104) execute simulation codes implementing the several distributed sub-functionalities of the specific functionality of the simulator.

In the example illustrated in FIG. 3, the first functionality of the simulator implemented by the first sub-system 350 may consist of two distributed sub-functionalities, implemented respectively by the simulation code executed by the processors 20 of the two configurable modular cards 101 and 102. The second functionality of the simulator implemented by the second sub-system 360 may consist of two distributed sub-functionalities, implemented respectively by the simulation code executed by the processors 20 of the two configurable modular cards 103 and 104.

The simulator 300 may comprise more than one simulation controller. For instance, the simulation controller 310 is responsible for controlling the configurable modular cards 101, 102, 103 and 104 of the sub-systems 350 and 360; and another simulation controller (not represented in FIG. 3) may be responsible for controlling the configurable modular cards of at least one other sub-system (not represented in FIG. 3). Furthermore, a configurable modular card 100 may be configured and used as a simulation controller.

The simulator 300 may also comprise a hierarchy of systems and sub-systems controlled by a hierarchy of simulation controllers. For example, the second sub-system 360 may include at least one lower level sub-system 365. The configurable modular card 103 may be configured to perform simulation controller functionality, similar to the simulation controller 310. Thus, the configurable modular card 103 is controlled by the simulation controller 310, and controls configurable modular cards (not represented in FIG. 3) of the lower level sub-system 365.

The simulation code executed by the processor 20 of the configurable modular card (e.g. 101) may be initially stored in the memory 30 of the configurable modular card. The simulation code may be divided in multiple modules implementing the various functionalities and sub-functionalities of the simulator. Thus, the processor 20 may select to execute a particular software module, corresponding to the functionality or sub-functionality specified by the configuration parameters of the received broadcast response message. Alternatively, the particular software of the configurable modular card may not be initially stored in the memory 30, and the configurable modular card (e.g. 101) may need to download it, for example from a pre-defined software server or from the simulation controller 310.

As mentioned earlier in reference to FIGS. 1 and 2, the configurable I/O unit 40 of a configurable modular card (e.g. 101) is capable of exchanging (receiving and sending) data with at least one other simulation component.

The other simulation component may consist of another configurable modular card 100. For example, the configurable modular cards 101 and 102 exchange data generated by the simulation code executed by the processors 20 of the configurable modular cards 101 and 102. Each modular card 101 and 102 implements a distributed sub-functionality of the global functionality implemented by the sub-system 350. The exchange of data enables a synchronization of the sub-functionalities implemented respectively by the configurable modular cards 101 and 102. Similarly, an exchange of data enables a synchronization of the sub-functionalities implemented respectively by the configurable modular cards 103 and 104. Each modular card 103 and 104 implements a distributed sub-functionality of the global functionality implemented by the sub-system 360. Although not represented in FIG. 3, configurable modular cards of different sub-systems (e.g. 102 and 103) may also exchange data.

The other simulation component may also consist of a dedicated hardware component 320, 321 and 322. A dedicated hardware component such as a display, a light, a mechanical actuator, is under the control of one or several configurable modular cards 100. In this case, the data exchanged there between consist of commands generated by the simulation software executed by the processor 20 of the configurable modular cards 100. The commands are sent to the dedicated hardware component to trigger an event representative of the current state of the simulation. Alternatively, a dedicated hardware component may consist of a sensor, and the data exchanged between the sensor and one or several configurable modular cards 100 consist in data collected by the sensor and sent to the configurable modular card(s).

In the example illustrated in FIG. 3, the functionality implemented by the first sub-system 350 simulates a motion of an aircraft and the functionality implemented by the second sub-system 360 simulates information displayed on a display. The dedicated hardware component 321 is a mechanical actuator for moving a seat in which a trainee is sitting, and is controlled by the configurable modular card 101. The dedicated hardware component 322 is a light or a set of lights representative of various events occurring during the motion of the aircraft, and is controlled by the configurable modular card 102. The dedicated hardware component 320 is a display for displaying data, and is controlled simultaneously by the configurable modular cards 103 and 104. Those skilled in the art will understand that the functionality is not limited to the example of FIG. 3, and other functionalities and sub-systems such as the following could be implemented by the present modular card: vehicle components, aircraft components, avionics equipment, cockpit panels, vehicle panels, etc.

In a particular aspect, the I/O unit 311 of the simulation controller 310 receives a test notification with test results from one (e.g. 101) of the plurality of configurable modular cards. The processor 312 of the simulation controller 310 analyses the test results, determines an operational status of the configurable modular card (e.g. 101), and determines reconfiguration parameters based on the test results and the previously determined configuration parameters. For example, if the configurable modular card 101 in charge of controlling the mechanical actuator 321 is not operating properly, the configurable modular card 102 may be reconfigured to control the actuator 321. The configurable modular card 102 may be reconfigured to only control the actuator 321, or may be reconfigured to simultaneously control the actuator 321 and the light(s) 322. Alternatively, a configurable modular card (e.g. 104) of the other sub-system 360 may be reconfigured to control the actuator 321. Thus, the reconfiguration parameters may affect one or several configurable modular cards (e.g. 102 or 104) of one or several sub-systems (e.g. 350 or 360).

The I/O unit 311 of the simulation controller 310 sends a reconfiguration request with the reconfiguration parameters to the configurable modular card(s) (e.g. 102) which need to be reconfigured.

Upon reception of the reconfiguration request by the configurable I/O unit 40 of a configurable modular card (e.g. 102), its processor 20 executes the input/output configuration code to reconfigure the plurality of inputs and outputs of its configurable I/O unit 40 based on the reconfiguration request. The processor 20 also executes the power supply configuration code to reconfigure the plurality of power circuits of the power supply 60 based on the reconfiguration request. The processor 20 further executes a simulation code to implement a functionality or sub-functionality of the simulator, the executed simulation code being determined based on the reconfiguration request. For example, the processor 20 of the configurable modular card 102 executes simulation code to control the actuator 321 instead of the previously executed simulation code for controlling the light(s) 322.

Referring now to FIG. 6, a first example of a simulator comprising a plurality of configurable modular cards for performing a distributed simulation is represented. FIG. 6 illustrates a flight simulator 600 including a simulation controller 610 and a hierarchy of configurable modular cards (631, 632, 641, 642, 652, 661 and 671).

The flight simulator 600 comprises a first sub-system 620 for simulating a first functionality of an aircraft: the engines. The sub-system 620 comprises two lower level sub-systems 630 and 640 for respectively simulating a left engine and a right engine of the aircraft.

The configurable modular cards 631 and 632 are in charge of the simulation of the left engine. The cards 631 and 632 are directly configured and controlled by the simulation controller 610. The cards 631 and 632 control several dedicated hardware components: displays 635, lights 636 (dedicated to the left engine simulation); and cabin actuators 635 (shared between the left and right engine simulation).

The configurable modular cards 641 and 642 are in charge of the simulation of the right engine. The cards 641 and 642 are directly configured and controlled by the simulation controller 610. The cards 641 and 642 control several dedicated hardware components: displays 645, lights 646 (dedicated to the right engine simulation); and cabin actuators 635 (shared between the left and right engine simulation).

The flight simulator 600 comprises a second sub-system 650 for simulating a second functionality of the aircraft: the landing gear. The sub-system 650 comprises two lower level sub-systems 660 and 670 for respectively simulating left wheels and right wheels of the aircraft.

The configurable modular card 652 is in charge of the simulation of the common functionalities of the landing gear sub-system 650. The card 652 is directly configured and controlled by the simulation controller 610. The card 652 control several dedicated hardware components: hydraulic circuits 655 and electric circuits 656.

The simulation sub-controller 651 is in charge of the control of the lower level sub-systems 660 and 670 of the sub-system 650. The simulation sub-controller 651 is directly configured and controlled by the simulation controller 610. The simulation sub-controller 651 may interact with the card 652 to control the lower level sub-systems 660 and 670. The simulation sub-controller 651 functionality may be integrated in the card 652.

The configurable modular card 661 is in charge of the simulation of specific functionalities of the left wheels. The card 661 is configured and controlled by the simulation sub-controller 651. The card 661 controls several dedicated hardware components: lights 665 (dedicated to the left wheels simulation); and cabin actuators 657 (shared between the left and right wheels simulation).

The configurable modular card 671 is in charge of the simulation of specific functionalities of the right wheels. The card 671 is configured and controlled by the simulation sub-controller 651. The card 671 controls several dedicated hardware components: lights 675 (dedicated to the right wheels simulation); and cabin actuators 657 (shared between the left and right wheels simulation).

Configurable Simulator with Integrated Testing Capabilities

Now referring back concurrently to FIGS. 1 and 3, in another aspect, the simulator 300 comprises integrated testing capabilities. The simulation controller 310 manages a series of tests executed by the plurality of configurable modular cards (101, 102, 103 and 104) under its control, and centralizes the results of the tests.

In one embodiment, the configurable modular cards (e.g. 101) have auto-testing capabilities. They autonomously perform a series of tests, and report the test results to the simulation controller 310. The tests are performed by the processor 20 (execution of a testing code) of the configurable modular card (e.g. 101) and the test results are transmitted to simulation controller 310 via a test notification. The test notification is generated by the processor 20 by aggregating the test results, and is transmitted by the configurable I/O unit 40 of the configurable modular card (e.g. 101).

The I/O unit 311 of the simulation controller 310 receives the test notification, and its processor 312 processes the test results present in the test notification. Processing the specific test results corresponding to a specific configurable modular card (e.g. 101) allows a determination of an operational status of the specific configurable modular card (e.g. 101). Based on the test results received from the plurality of configurable modular cards (101, 102, 103 and 104) under its control, the simulation controller 310 maintains a global operational status of all the configurable modular cards under its control.

As previously described, the simulation controller 310 may trigger a reconfiguration of some of the configurable modular cards (101, 102, 103 and 104) under its control, based on their global operational status. For instance, the configurable modular card 102 may be reconfigured to implement a functionality previously implemented by the configurable modular card 101, due to a failure of the configurable modular card 101 detected by the series of tests performed on this card.

As previously described with reference to FIG. 1, the testing code executed by the processor 20 of a configurable modular card (e.g. 101) comprises generating testing signals to the plurality of inputs and outputs of its configurable I/O unit 40 configured based on the broadcast response message received by the configurable I/O unit 40. The testing code executed by the processor 20 of a configurable modular card (e.g. 101) also comprises generating testing signals to the plurality of power circuits of the power supply 60 configured based on the broadcast response message received by the configurable I/O unit 40.

Additionally, the testing code executed by the processor 20 of a configurable modular card (e.g. 101) further comprises monitoring the execution of the simulation code executed by the processor 20.

The simulation code executed by the processor 20 implements a functionality of the simulator 300. Functionality may be divided in several distributed sub-functionalities, each specific sub-functionality being implemented by a specific configurable modular card 100. Thus, monitoring the execution of the simulation code may consist in monitoring the code corresponding to a specific sub-functionality. If a configurable modular card 100 implements several sub-functionalities, the testing code may only monitor a subset of these sub-functionalities.

As previously described, the simulation code executed by the processor 20 of the configurable modular card (e.g. 101) may comprise code for controlling a dedicated hardware component (e.g. 321) by means of control commands sent to this dedicated hardware component (e.g. 321). For example, the dedicated hardware component 321 is a mechanical actuator for moving a seat in which a trainee is sitting. In this case, executing the testing code further comprises generating testing signals to the dedicated hardware component (e.g. 321) to verify that this dedicated hardware component is operating according to the control commands it has received from its controlling configurable modular card (e.g. 101).

In another embodiment, the configurable modular cards (e.g. 101) execute a series of tests determined by the configuration controller 310. The execution of the testing code by the processor 20 of a specific configurable modular card (e.g. 101) is triggered by the reception of a test request received from the simulation controller 310. The test request specifies at least one specific test to be performed via the execution of the testing code by the processor 20. The at least one specific test includes one of: testing the inputs and outputs of the configurable I/O unit 40, testing the plurality of power circuits of the power supply 60, monitoring the execution of the simulation code by the processor 20, and generating testing signals to another simulation component (e.g. 321).

Referring now to FIG. 4, a simplified version of the configurable modular card 100 of FIG. 1 is represented, illustrating the configuration parameters and software codes of the card 100. The memory 30 of the card 100 stores configuration parameters, a configuration code, a simulation code and a testing code.

The configuration parameters of the card 100 are initially stored in a memory (not represented in FIG. 4) of a configuration component 410; and transmitted to the memory 30 through the configurable I/O unit 40 of the card 100, via the aforementioned broadcast message 120/broadcast response message 121. The configuration component 410 corresponds to one of the configuration component 210 represented in FIG. 2 or the simulation controller 310 (having configuration capabilities) represented in FIG. 3.

The simulation code executed by the card 100 is also initially stored in the memory of the configuration component 410; and transmitted to the memory 30 through the configurable I/O unit 40. The aforementioned broadcast message 120/broadcast response message 121 may be used for this purpose. Another transmission mechanism may also be used for this purpose. Alternatively, the simulation code may be initially stored in the memory 30, or transmitted by a software server (not represented in FIG. 4).

The memory 30 stores the configuration code, which is executed by the processor 20 of the card. For instance, the configuration code stored in the memory 30 includes a power supply configuration code, which when executed by the processor 20 configures the power supply 60 of the card 100, based on specific configuration parameters related to the power supply 60 and stored in the memory 30. The configuration code stored in the memory 30 also includes an I/O unit configuration code, which when executed by the processor 20 configures the configurable I/O unit 40, based on specific configuration parameters related to the configurable I/O unit 40 and stored in the memory 30.

The processor 20 executes the simulation code stored in the memory 30. The simulation code may include a plurality of software modules, corresponding to several simulation functionalities and sub-functionalities. The execution of specific software modules, and the order in which they are executed, may be determined by specific configuration parameters related to the simulation flow and stored in the memory 30.

The memory 30 stores the testing code, which is executed by the processor 20. The testing code may be initially stored in the memory 20, or transmitted by the configuration component 410, or by a software server (not represented in FIG. 4). For instance, the testing code stored in the memory 30 includes a power supply testing code, which when executed by the processor 20 tests the power supply 60. The testing code stored in the memory 30 also includes an I/O unit testing code, which when executed by the processor 20 tests the configurable I/O unit 40. The testing code stored in the memory 30 further includes simulation testing code, which when executed by the processor 20 monitors the execution of the simulation code.

Method for Operating a Configurable Simulator Comprising a Plurality of Configurable Modular Cards

Referring now concurrently to FIGS. 4 and 5, a method 500 for operating a configurable simulator comprising a plurality of configurable modular cards is represented.

The configurable simulator operated by the method 500 may correspond to the simulator 200 previously described in relation to FIG. 2 and/or to the simulator 300 previously described in relation to FIG. 3. The configurable simulator comprises a plurality of configurable modular cards corresponding to the cards 100 previously described in relation to FIGS. 1 and 4. For simplification purposes, only two configurable modular cards 504 and 506 are represented in FIG. 5, but the simulator may include any number of configurable modular cards. A simulation controller 502 is represented in FIG. 5, corresponding to the configuration components 210 and 410 previously described in relation to FIGS. 2 and 4, and/or to the simulation controller 310 previously described in relation to FIG. 3. The simulation controller 502 may be integrated to the configurable simulator, or may be an external component in communication with the configurable simulator by means of a communication protocol such as the Ethernet protocol or the Wi-Fi protocol.

The method 500 comprises storing 510 configuration parameters for the plurality of configurable modular cards (504 and 506) in a memory (not represented) of the simulation controller 502.

The method 500 comprises storing 520 a configuration code, a simulation code and a testing code in a memory 30 of the plurality of configurable modular cards (504 or 506). In a particular aspect, at least one of the configuration code, the simulation code and the testing code may be stored in a memory of the simulation controller 502 and transmitted from the simulation controller 502 to the card (504 or 506). Alternatively, the codes are initially present in the memory 30 of the card (504 or 506).

The method 500 comprises transmitting specific configuration parameters for a specific card (504 or 506) from the simulation controller 502 to the card (504 or 506). Thus, each card (504 or 506) may have its own specific configuration parameters, generated and stored at the simulation controller 502. In a particular aspect, transmitting the specific configuration parameters comprises sending 525 a broadcast message from the card (504 or 506) to the simulation controller 502, and receiving 526 a broadcast response message with the specific configuration parameters from the simulation controller 502 at the card (504 or 506).

The method 500 comprises storing 530 the received specific configuration parameters in the memory 30 of the card (502 or 504).

The method 500 comprises executing 540 the configuration code by a processor 20 of the card (504 or 506) based on the specific configuration parameters of the card.

Executing the configuration code includes configuring a plurality of inputs and outputs of a configurable input/output (I/O) unit 40 of the card (504 or 506) based on the specific configuration parameters of the card.

In a particular aspect, configuring the plurality of inputs and outputs of the configurable I/O unit 40 comprises performing a network configuration of the inputs and outputs.

In another particular aspect, the configurable I/O unit 40 exchanges data with at least one other simulation component. Configuring the plurality of inputs and outputs of the configurable I/O unit 40 may comprise determining which inputs and outputs exchange the data with the at least one other simulation component. The at least one other simulation component may be another configurable modular card. For instance, the cards 504 and 506 may exchange data via their respective I/O units 40. Alternatively, the at least one other simulation component may be a dedicated hardware component (not represented in FIG. 5) controlled by the card (502 or 504). The dedicated hardware component may be one of the following: a sensor, a display, a light, a switch, a mechanical actuator, a pneumatic actuator, a hydraulic actuator and an electric component.

Executing the configuration code also includes configuring a plurality of power circuits of a power supply 60 of the card (504 or 506) based on the specific configuration parameters of the card.

In a particular aspect, configuring the plurality of power circuits of the power supply 60 comprises determining at least one of: a specific amperage and a specific voltage of the power delivered by the specific power circuit to an electronic component. The electronic component may be located on the card (504 or 506) or on a dedicated hardware component controlled by the card.

The method 500 comprises executing 550 the simulation code by the processor 20 of the card (504 or 506) to implement a functionality of the simulator. Executing the simulation code to implement a functionality of the simulator may comprise at least one of: simulating information shown on a display, simulating a motion of an aircraft, simulating electric circuits of an aircraft, simulating hydraulic circuits of an aircraft. The simulation code executed by the processor 20 may also comprise code for controlling the aforementioned dedicated hardware component(s).

In a particular aspect, several configurable modular cards (e.g. 504 and 506) receive specific configuration parameters from the simulation controller 502 for configuring their respective processors 20 to execute simulation codes implementing several distributed sub-functionalities of a particular functionality of the simulator.

The memory 30 of the card (504 or 506) may store a plurality of simulation codes corresponding to several functionalities of the simulator. Executing the configuration code may further comprise determining the simulation code executed by the processor 20 among the plurality of simulation codes stored in the memory 30 based on the specific configuration parameters of the card.

The method 500 comprises executing 560 the testing code by the processor 20 of the card (504 or 506).

Executing the testing code includes generating testing signals to the plurality of inputs and outputs of the configurable I/O unit 40 configured based on the specific configuration parameters of the card (504 or 506).

In a particular aspect, the testing signals generated to the plurality of inputs and outputs of the configurable I/O unit 40 allow a verification of the network configuration of the inputs and outputs.

In another aspect, the testing signals generated to the plurality of inputs and outputs of the configurable I/O unit 40 allow a verification of the network connectivity of the inputs and outputs with another simulation component (e.g. another configurable modular card or a dedicated hardware component).

Executing the testing code also includes generating testing signals to the plurality of power circuits of the power supply 60 configured based on the specific configuration parameters of the card (504 or 506).

In a particular aspect, the testing signals generated to the plurality of power circuits of the power supply 60 allow a verification that the power circuits are operating at a specified voltage or amperage.

Executing the testing code further includes monitoring the execution of the simulation code by the processor 20 of the card (504 or 506).

The method 500 may comprise generating by the processor 20 of the card (504 or 506) a test notification sent 565 by the configurable I/O unit 40 of the card to the simulation controller 502 with test results of the testing code executed by the processor 20 of the card.

The method 500 may also comprise determining 570 at the simulation controller 502 new configuration parameters for at least one of the plurality of configurable modular cards (e.g. 504) based on the received test results. The new configuration parameters are sent 575 to each of the impacted cards (e.g. 504). Then, each impacted card (e.g. 504) executes 580 its configuration code based on the received new configuration parameters and reconfigures itself.

The method 500 may further comprise triggering 555 the execution of the testing code at a card (e.g. 504) by the reception of a test request from the simulation controller 502.

Pre-Acceptance and Acceptance Testing

So far, the integrated testing capabilities of the simulator 300 addressed testing needs during a simulation where the simulator 300 is deployed and operated in an exploitation environment. However, other testing needs exist for the simulator 300 before it is delivered to a customer, or after an update of the simulator 300 In particular, to provide an accurate simulation experience, the simulator 300 shall be updated to include the changes introduced to real life systems corresponding to the simulator 300. Furthermore, as new scenarios are encountered by the real life systems, the simulator 300 must be updated to include these new scenarios. Before releasing a new or an improved or a modified simulator 300, a series of tests must be performed. The series of tests include system tests, integration tests and acceptance tests. The acceptance tests correspond to sets of verifications that must be performed to confirm that the improved or modified simulator 300 fulfills predetermined procedures, such as for example standards checklists execution or specific customer requirements.

Acceptance tests are usually performed after the system tests and integration tests are completed. However, the costs of correcting deficiencies after identification of malfunctions during acceptance tests are very expensive, and may delay the delivery of the simulator 300. Thus, the following paragraphs describe a solution to allow performing acceptance tests earlier in the production of the simulator 300, or earlier in the implementation of improvements and/or modifications to the simulator 300.

For clarification purposes, the following terminology is introduced, for use in the following paragraphs.

Unitary test: A test or series of tests that demonstrate functionalities of a small software module. This small software module cannot be used alone (hardware analogy: testing a resistor).

System test: A test or series of tests that demonstrate functionalities and compliance to a specification for the given software assembly (hardware analogy: testing a power supply).

Integrated test: A test or series of tests that demonstrate functionalities and compliance to a specification for a given set of several software assemblies (hardware analogy: testing a power supply with an audio amplifier).

Acceptance test: A test or series of tests that demonstrate compliance to customer specifications or standard security standards for the simulator to be delivered (hardware analogy: testing the manufactured audio amplifier with a set of speakers).

Simulated panel: A replica of an equipment connected to an electronic board of a simulated vessel.

In the following, a method and a testing platform providing pre-acceptance testing earlier in the manufacturing and/or integration process is described. The method and testing platform provide hardware and software simulation (flight model, motion model, simulated aircraft systems . . . ) pre-acceptance testing at the three following levels: system tests, integration tests and acceptance tests. The method and testing platform also provide hardware panel interface validation in an operational environment (i.e. from a pilot/user perspective) of the simulator 300.

The testing platform sub-divides the simulator 300 into autonomous and decoupled configurable modular cards (for example cockpit modules). Each configurable modular card comprises a simplified testing interface including an Ethernet connection and power. By means of the Ethernet connection and power, each configurable modular card or specific components thereof may be tested for pre-acceptance before installation on site. One or multiple configurable modular cards 100 of the simulator 300 may implement each functionalities, the I/O unit 40 providing the Ethernet connection and the power supply 60 the power. By pre-accepting configurable modular cards or components thereof, it is possible to reduce the need of test sites. Furthermore, by pre-accepting configurable modular cards, only inter-configurable modular cards connections need to be validated and/or accepted after introduction in the simulator 300.

There are different types of pre-acceptance tests: semi-automatic pre-acceptance tests and automatic pre-acceptance tests. The semi-automatic pre-acceptance tests correspond to tests requiring interactions with an employee on the production chain, and/or with a user of the simulator 300. The goal of the semi-automatic pre-acceptance tests is to confirm that the hardware in the simulator 300 functions as required. For example, a reading of a gauge in the simulator 300 must correspond to a specific value. As the pre-acceptance test is performed early on in the production or integration of modifications, only the predetermined value is tested, and calibration could be performed afterwards. An example of such a semi-automatic pre-acceptance test for reading a gauge is illustrated in FIG. 7.

The automatic pre-acceptance test is a unitary test, which may be executed during the building of the software on a software production line. The automatic pre-acceptance tests may focus on the internal logic of the cockpit module, or alternatively on the simulator 300 as a whole. The automatic pre-acceptance tests may be executed in real-time, or on down time. When executed on down time, the automatic pre-acceptance tests may greatly assist in validating large number of functionalities of the simulator 300. The automatic pre-acceptance tests also prevent regressions in the production chain, as they are executed upon building the software, instead of being executed upon system integration. The automatic pre-acceptance tests may also be used as validation criteria in a continuous integration process.

A database of pre-acceptance tests to be performed on a per component (hardware and/or software) or on a per configurable modular card basis is put in place. The pre-acceptance tests are similar to the acceptance tests usually performed by a user upon delivery of the simulator 300. The acceptance tests are generally executed during an acceptance flight, which formally confirms that the simulator 300 is compliant with the client specifications and/or requirements, and/or industry security standards. The notion of acceptance tests in the aeronautics industry, and more specifically in the aircraft simulation industry, is well known to persons skilled in the art. More information on acceptance tests, also sometimes known as qualification flight, can be found on in various sources such as Internet.

To create the database of pre-acceptance tests, the various levels of tests must be sub-divided into series of unitary tests, system tests, integration tests and pre-acceptance tests. By sub-dividing the tests in this manner, pre-acceptance tests can be performed during the development of the simulator 300, and of configurable modular cards and/or components thereof; as well as during the integration of the simulator 300. The sub-division further includes an indication as to whether a particular pre-acceptance test is automatic or semi-automatic.

In an embodiment of the method and testing platform for providing pre-acceptance testing, the structure of the test information stored in the database is standardized for the various types of tests (unitary tests, integration tests, and system tests). Following is an example of such a structure:

-   -   Suite100FunctionalTests     -   Suite200CircuitBreakersTests     -   Suite300MalfunctionsTests     -   Suite400InstructorActionstests

To better understand the implications of the testing structure put in place to support pre-acceptance testing, an example is now provided. In the simulator 300, a fuse commanding a retractable light on a wing of an airplane is tested at the integration level, in order to confirm proper interactions between the visual systems. However, a fuse commanding a fuel pump may be tested at the system level and/or automatically as the result is used by the simulator 300, and not interacting with a user of the simulator 300. Functioning of a hydraulic pump may also be tested at the system or automatic level. The present structure thus duplicates to each type of test where it should be tested, so as to simplify its usage throughout the testing at the system, integration and pre-acceptance levels.

The simulation industry has put in place standard Aeronautical Radio, Incorporated (ARINC) 610B, which identifies certain rules to be followed for the interactions between an instructor and a simulator 300. However, no rule has been put in place when a system reset is effectuated. In the context of pre-acceptance testing, pre-acceptance tests may be specified to ensure that the component, configurable modular card and system response remains the same from one version to another.

To address this new requirement, each pre-acceptance test is provided with a logical sequence for systems and integrated system tests as follows:

-   -   A) All power OFF->What does the component/configurable modular         card/system does when the <<power>> is turned off in the         cockpit. If “PRESS TO TEST” is pressed, what happens?     -   B) Same question for the battery.     -   C) Same question for alternate current (engines or APU or         external).     -   D) Same question in operation.

Tests of the type <<All power off>> are mandatory. The other tests are mutually exclusive.

Reference is now made concurrently to FIGS. 8 and 10, which are respectively a schematic representation of a simulator 900 comprising a testing platform 910 to perform pre-acceptance testing of software components/configurable modular cards, and a method 1100 of performing pre-acceptance testing. The testing platform 910 connects to a simulation engine 940, through a simulation database 920, so as to trigger simulation tests performed by the simulation engine 940 and corresponding to the software component/configurable modular card being tested. For doing so, the testing platform 910 initiates a simulation. Then, the testing platform 910 introduces an action of a scenario of the simulation database 920. The action is introduced by a command issued by the testing platform 910 to the simulation database 920, which in turn forces the simulation engine 940 to perform a specific action. The testing platform 910 further collects a resulting state of the simulation, via the simulation database 920, and compares the collected resulting state with the expected result for the scenario. The pre-acceptance testing may be performed after introduction of a new component (either a new hardware component, a new software component, a combination of both), of a configurable modular card.

The simulation database 920 may comprise several types of information. For example, the simulation database 920 may include the various types of tests to be performed before releasing the simulator 900. The simulation database 920 may thus include unitary tests, system tests, integration tests, acceptance tests and pre-acceptance tests. Alternatively, the various tests may be stored in a database (not represented in FIG. 8) complementary to the simulation database 920. The simulation database 920 may further store scenarios to be executed by a user of the simulator 900. Each scenario includes a series of events and corresponding states. Depending on the decisions made by the user of the simulator 900, the simulator 900 executes various aspects of the scenario, and may go through a series of scenarios during one simulation. As a scenario typically includes a series of events, the pre-acceptance testing platform 910 may also consecutively introduce a plurality of events, and collect the corresponding states of one or several specific components of the simulator 900 until all events of a scenario are completed.

Reference is now concurrently made to FIGS. 8-10, where FIG. 9 is a schematic representation of the simulator 900 with the testing platform 910 to perform pre-acceptance testing of hardware components. To perform pre-acceptance testing of hardware components, the testing platform 910 connects to a hardware component 930 (e.g. a physical aircraft panel as illustrated in FIG. 9) and requests the hardware component 930 to set itself to a predetermined state or value. For example, in the case of the physical aircraft panel 930, the request consists in a desired switch position. Upon execution of the request by the hardware component 920, the simulation database 920 is informed by the hardware component 930 of its change of state or value; and the simulation database 920 is updated accordingly. Alternatively, instead of interacting directly with a specific hardware component 930, the testing platform 910 may connect to one of the configurable modular cards (not represented in FIG. 9) of the simulator 900, which includes the hardware component 930 and send the request to that particular configurable modular card. Upon update of the state or value of the hardware component 930, and update of the simulation database 920, the simulation engine 940 performs the simulation with the updated state or value and returns a new state, as previously described for the software component. Thus, when pre-acceptance testing is to be performed on hardware components 930, the requests are first sent to the hardware component 930 itself or to the corresponding configurable modular card by the testing platform 910, and the modified state or value is reported by the hardware component 930 to the simulation database 920 and used in the execution of the simulation.

For exemplary purposes, FIG. 11 is a graphical representation of a hardware component and corresponding pre-acceptance testing scenarios to be performed. Correspondingly, FIG. 12 is a graphical representation of a pre-acceptance testing scenario for software component. In turn, FIG. 13 is a graphical representation of a pre-acceptance testing scenario for a component comprising hardware and software aspects. Once the pre-acceptance testing has been performed for one or a plurality of components, a report may be generated on a per-component or a per configurable modular card basis, so as to promptly identify any problem to be addressed. An example of such a report is provided in FIG. 14.

FIG. 15 is a schematic representation of an exemplary sub-division of tests including pre-acceptance tests. As can be appreciated, the various types of tests, i.e. unitary tests, system tests, integration tests and pre-acceptance tests, could be inter-linked so as to clarify the relations there between, and ensure that any problem identified at one level, can also be promptly translated into the other levels of testing and addressed appropriately.

Automatic pre-acceptance testing may be based for example on:

-   -   FitNesse™ software     -   Fitsharp™: software plugin for FitNesse™ that allows to create         an interface between Fitnesse™ and a particular testing software         called Fixture, and written in CSharp™     -   Fixture: software that interacts with the simulation database,         and which is underlying with each simulation. In case of         interaction with a physical component, the Fixture instead of         interacting with the simulation database requests the         corresponding simulated panel to send the same command as if a         user of the simulator did the physical action on the panel         (moving a switch for example).

Automatic pre-acceptance testing may use:

-   -   Test scripts written in natural language. The test scripts are         compatible with Fitnesse™. Fitnesse™ reads the scripts and uses         Fitsharp™ interface calls up to the Fixture.     -   Several libraries organized in layers. Each layer contains some         specific Fixtures. The lowest layer contains the interface with         the hardware panels or the simulation database. For example, in         the context of a flight simulator, the lowest layer is not         aircraft specific, the middle layer correspond to         actions/reactions visible by the simulator instructor. The         highest layer is aircraft specific.     -   Fitnesse™ to report test results consultable by a human.

Automatic pre-acceptance testing replicate actions performed by the users (for example pilots and or instructors), and verify expected reactions from the “real life systems”. So far, the integrated testing capabilities of the simulator 300 addressed testing needs during a simulation where the simulator 300 is deployed and operated in an exploitation environment. However, other testing needs exist for the simulator 300 before it is delivered to a customer. In particular, to provide an accurate simulation experience, the simulator 300 must be updated to include the changes introduced to the real life systems. Furthermore, as new scenarios are encountered by the real life systems, the simulator 300 must be updated to include the new scenarios. Before releasing a new or an improved or modified simulator 300, a series of tests must be performed. The series of tests include system tests, integration tests and acceptance tests. The acceptance tests correspond to sets of verifications that must be performed to confirm that the improved or modified simulator 300 fulfills predetermined procedures, such as for example standards checklists execution or specific customer requirements. Acceptance tests are usually performed after the systems tests and integration tests are completed. However, the costs of correcting deficiencies after identification of malfunctions during acceptance tests are very expensive, and delay the delivery of the simulator 300.

The present disclosure has introduced a configurable simulator comprising a plurality of configurable modular cards. The usage of these cards introduces a great deal of flexibility in the operations of the simulator. Each card being individually configurable (and reconfigurable), the simulator can be easily (re)configured to accommodate an addition of card(s), a removal of card(s), a replacement of card(s). The simulator can also be reconfigured to adapt to one or several of its cards being out of order. Configuring or reconfiguring the simulator consists in configuring or reconfiguring one or several of its cards. Thus, a complete simulator, or a sub-system of a complete simulator, may be designed based on a set of configurable modular cards. The set of configurable modular cards is delivered as a set of generic cards having a common hardware and no initial specific hardware and software configuration. The set of configurable modular cards is then configured as illustrated in the present disclosure, to implement the multiple functionalities of a complete simulator, or alternatively to implement a particular functionality of a sub-system of a complete simulator.

Although the present disclosure has been described hereinabove by way of non-restrictive, illustrative embodiments thereof, these embodiments may be modified at will within the scope of the appended claims without departing from the spirit and nature of the present disclosure. 

What is claimed is:
 1. A configurable simulator with testing capabilities, comprising: at least one simulation controller, comprising: an input/output unit for: receiving a broadcast message from a plurality of configurable modular cards; sending a broadcast response message with configuration parameters to the plurality of configurable modular cards; and receiving a test notification with test results from one of the plurality of configurable modular cards; a processor for: determining the configuration parameters of the plurality of configurable modular cards based on a pre-defined configuration of the simulator; and processing the test results to determine an operational status of the one of the plurality of configurable modular cards; the plurality of configurable modular cards, each card comprising: a configurable input/output unit comprising a plurality of configurable inputs and outputs, the configurable input/output unit having a predefined output for sending the broadcast message and a predefined input for receiving the broadcast response message; a power supply comprising a plurality of configurable power supply circuits; and at least one processor for: executing an input/output configuration code to configure the plurality of inputs and outputs of the configurable input/output unit based on the broadcast response message received by the configurable input/output unit, executing a power supply configuration code to configure the plurality of power circuits of the power supply based on the broadcast response message received by the configurable input/output unit, executing a simulation code to implement a functionality of the simulator, the executed simulation code being determined based on the broadcast response message received by the configurable input/output unit; executing testing code for: generating testing signals to the plurality of inputs and outputs of the configurable input/output unit configured based on the broadcast response message, generating testing signals to the plurality of power circuits of the power supply configured based on the broadcast response message, and monitoring the execution of the simulation code; and generating the test notification sent by the configurable input/output unit to the simulation controller with the test results of the testing code executed by the processor.
 2. The simulator of claim 1, wherein configuring the plurality of inputs and outputs of the configurable input/output unit comprises performing a network configuration of the inputs and outputs.
 3. The simulator of claim 1, wherein the configurable input/output unit exchanges data with at least one other simulation component.
 4. The simulator of claim 3, wherein configuring the plurality of inputs and outputs of the configurable input/output unit comprises determining which inputs and outputs exchange the data with the at least one other simulation component.
 5. The simulator of claim 3, wherein the at least one other simulation component is a dedicated hardware component controlled by the configurable modular card.
 6. The simulator of claim 5, wherein the dedicated hardware component is one of the following: a sensor, a display, a light, a switch, a mechanical actuator, a pneumatic actuator, a hydraulic actuator and an electric component.
 7. The simulator of claim 5, wherein the simulation code executed by the processor of the configurable modular card comprises code for controlling the dedicated hardware component and the exchanged data comprise control commands for the dedicated hardware component.
 8. The simulator of claim 7, wherein executing the testing code further comprises generating testing signals to the dedicated hardware component to verify that the dedicated hardware component is operating according to the control commands.
 9. The simulator of claim 1, wherein configuring the plurality of power circuits of the power supply comprises determining at least one of: a specific amperage and a specific voltage of the power delivered by the specific power circuit.
 10. The simulator of claim 1, wherein the functionality of the simulator comprises several sub-functionalities.
 11. The simulator of claim 10, wherein configuring the plurality of inputs and outputs of the configurable input/output unit comprises determining which inputs and outputs are used to receive and send data related to a specific sub-functionality.
 12. The simulator of claim 10, wherein monitoring the execution of the simulation code consists in monitoring the code corresponding to a specific sub-functionality.
 13. The simulator of claim 1, wherein the testing signals generated to the plurality of inputs and outputs of the configurable input/output unit allow a verification of the network configuration of the inputs and outputs.
 14. The simulator of claim 1, wherein the testing signals generated to the plurality of inputs and outputs of the configurable input/output unit allow a verification of the network connectivity of the inputs and outputs with another simulation component.
 15. The simulator of claim 1, wherein the testing signals generated to the plurality of power circuits of the power supply allow a verification that the power circuits are operating at a specified voltage or amperage.
 16. The simulator of claim 1, wherein the execution of the testing code is triggered by the reception of a test request received from the simulation controller.
 17. The simulator of claim 16, wherein the test request specifies at least one specific test to be performed via the execution of the testing code; wherein the at least one specific test consists of one of: testing the inputs and outputs of the configurable input/output unit, testing the plurality of power circuits of the power supply, monitoring the execution of the simulation code, and generating testing signals to a dedicated hardware component.
 18. The simulator of claim 1, wherein executing a simulation code to implement a functionality of the simulator comprises at least one of: simulating information shown on a display, simulating a motion of an aircraft, simulating electric circuits of an aircraft, simulating hydraulic circuits of an aircraft.
 19. The simulator of claim 1, wherein executing the testing code comprises performing pre-acceptance tests of at least one of: hardware components and software components of the card.
 20. The simulator of claim 19, wherein the pre-acceptance tests are performed at the three following levels: system tests, integration tests and acceptance tests. 